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TR/03/87 February 1987
The Influence of out-of-plane Stress on a Plane Strain Problem in Rock Mechanics
by
M. B. Reed
z1624889
THE INFLUENCE OF OUT-OF-PLANE STRESS ON A
PLANE STRAIN PROBLEM IN ROCK MECHANICS
M. B. REED
Department of Mathematics and Statistics
Brunel University
Uxbridge, U.K. Abstract
This paper analyses the stresses and displacements in a uniformly
prestressed Mohr-Coulomb continuum, caused by the excavation of an infinitely
long cylindrical cavity. It is shown that the solution to this axisymmetric
problem passes through three stages as the pressure at the cavity wall is
progressively reduced. In the first two stages i t is possible to determine
the stresses and displacements in the rθ -plane without consideration of the
out-of plane stress . In the third stage it is shown that an inner plastic
zone develops in which
zσ
zσ=σθ , so that the stress states lie on a singularity
of the plastic yield surface. Using the correct flow rule for this situation,
an analytic solution for the radial displacements is obtained. Numerical
examples are given to demonstrate that a proper consideration of this third
stage can have a significant effect on the cavity wall displacements.
-2- 1. Introduction
Many situations in geotechnical engineering, such as dams, embankments
and tunnels , can be t reated as cases of plane s t ra in; that is , there is no
displacement in the out-of-plane or z-direction, and the shear stresses xzτ
and are zero . I f the soi l or rock is e las t ic , then τ 0z =ε and the s t ress
and displacement analysis may be carried out purely in the xy-plane, with the out-of-plane stress found subsequently as νσ+σν=σ ),yx(z ,denoting the
poisson's ratio.
Even is the material is elastic-plastic, i t is often possible to ignore
the influence of the out-of-plane stress. This is because the most commonly-
used plastic yield criterion, that of Mohr-Coulomb, is expressed in terms of
the major and minor principal stresses 31σσ only, and zσ can often be shown
to be the intermediate principal stress at yield. However, this does not
imply that a remains intermediate throughout the deformation, and a complete
analysis should evaluate throughout the yield zone to demonstrate the validity
of this assumption.
zσ
One of the most important plane strain problems in rock mechanics is to
predict the stresses and deformations induced in a pre-stressed rock continuum
of infinite extent by the excavation of an infinitely long tunnel or cavity of
uniform cross-section. An axisymmetric version of this situation, in which the
tunnel has circular cross-section and the in situ stress field is of equal
magnitude in all directions, is amenable to analytic solution, and it is this
axisymmetric tunnel problem that will be considered in this paper.
Many rock mechanics texts (e.g. Jaeger & Cook 1979) feature the solution
for the radial and tangetial stresses θσσ ,r in the rock mass when an elastic-
brittle plastic material model is used with Mohr-Coulomb yield criterion, and
with the assumption that θσ≤σ≤σ zr throughout. (Because of the axisymmetry,
and aft are the principal stresses in the xy-plane.) The zone of yielded
rock forms an annulus around the tunnel, with a discontinuity in at the
rσ θσ
θσ
-3-
interface with the intact rock. The author (Reed 1986) has given an analytic
solution for the displacement field assuming θσ<σ<σ zr with a dilation flow
rule derived from the Mohr-Coulomb yield function. A lower limit on the tunnel
support pressure p was also derived, for which the above assumption on
remains valid. It is the purpose of this paper to analyse the problem when p
drops below this l imit.
zσ
In the following section the problem and notation are defined. The com-
plete solution to the problem is then shown to pass through three stages as the
tunnel support pressure is gradually reduced. The first stage is a standard
result of elasticity theory. In the second, a plastic zone develops in which
, and in the third an inner plastic zone forms in which
θθσ<σ<σ zr σ<σ<σ zr .
Stresses in this inner plastic zone lie on singular points of the Mohr-Coulomb
yield surface. The effect of this on the displacement solution is considered in sect ions 5 and 6, and i l lus t ra ted by graphs in sect ion 7.
2. Statement of the problem
The axisymmetric tunnel problem may be described as follows:- consider
a homogeneous isotropic rock mass, of infinite extent, with a uniform compressive in situ stress field of magnitude q in all directions. A long tunnel of
circular cross-section, radius r0, is now excavated in the rock mass; the
excavation process is represented by a gradual reduction in the normal support
pressure p on the tunnel wall from p = q to a final value p = p0 . The
problem is one of plane strain, and because of the axisymmetry it may be analysed
in the radial dimension. The unknowns are the stresses in the radial, tangential
and out-of-plane directions ( zr σθσσ ) which form the principal stress directions,
and the inward radial displacement u(r) at a radius r from the tunnel centre
(see fig. 1 ).
Tunnel wall Fig. 1
The rock is taken as a linear elastic-britt le plastic Mohr-Coulomb
material. That is, i t deforms elastically until the yield criterion
c31 k σ+σ=σ (1)
is satisfied. Here, and are the major and minor principal stresses, 1σ 3σ
k is the triaxial stress factor and cσ the unconfined compressive strength.
The last two parameters are related to the cohesion c and angle of internal
friction by φ
φ−φ
=σφ−φ+
=sin1cosc2,
sin1sin1k c (2)
After yield, the stress state is constrained to lie on the residual yield surface F = 0, where ~)(σ
.1c3
1k1)(F σ−σ−σ=σ (3)
Note that F is defined using the residual strength which is strictly less
than for a britt le rock, and residual triaxial stress parameter k ′ .
~ )(σ 1cσ
cσ After initial yield, the process of stress reduction is described by a flow ru le def ined in te rms of a p las t ic po ten t ia l Q )~(σ . I f s t ra ins a re sp l i t into elastic and plastic components, then the plastic strain increment is given by the flow rule
,~
Qd~p.
σ∂∂
λ=ε (4)
where is a constant multiplier. The flow rule is termed associated if Q = F;
we shall for generality consider a dilation flow rule defined by
λd
-5-
31)~(Q σ−σ=σ l (5)
where
,sin1sin1
ψ−ψ+
=l with ψ being an angle of dilation, 0 φ≤ψ≤ .
Note that the stress state must everywhere satisfy the equilibrium equation
rrd
rdr σ+σ=θσ (6)
and that the boundary conditions are
orratpr ==σ (7)
and .rasqz,,r ∞→→σθσσ (8)
3. Solution: first stage
As the tunnel support pressure p is gradually reduced, the stress solution
passes through three distinct stages. In the first stage, there is no plastic
yield in the rock, and standard elasticity theory (Timoshenko & Goodier 1951)
gives
qz
)r
20r()pq(q
)r
20r()pq(qr
=σ
−+=θσ
−−=σ
(9)
and radial displacement
.r/02r)pq(
Ev1)r(u −
+= (10)
This will continue until the stresses at the tunnel wall satisfy the yield
criterion (1), that is, when
.1k
q2pp c
+σ−
≡= (11)
4. Solution: second stage
From this point on, an annular zone of failed rock will grow outwards around
the tunnel. Let r denote the radius of the interface between the plastic zone
of failed rock and the surrounding mass of intact, elastic rock; the situation
-6-
i s i l lus t ra ted in f ig . 2 . A t l eas t in i t i a l ly , θσ<σ<σ zr a t a l l po in t s within the plastic zone.
Fig. 2 T h e s t r e s s s o l u t i o n m a y b e f o u n d ( F e n n e r 1 9 3 8 ) a s :
I n t h e e l a s t i c z o n e r > r :
,qz
2)rr()pq(q
2)rr()pq(qr
=σ
−+=θσ
−−=σ
(12)
Where p is defined in (11), and is the value of rσ at the interface.
-7-
In the plastic zone :rrr0 <≤
q)v21()r(vz
'p1'k)
0rr()'pp('k
'p1'k)
0rr()'pp(r
−θσ+σ=σ
−−
+=θσ
−−
+=σ
(13)
where .1'k
''p c
−σ
=
As the radial stress must be continuous at the interface, the radius r is
obtained as
.'pp'pprr 1'k
1
0−⎥
⎦
⎤⎢⎣
⎡++
= (14)
As mentioned previously, strains may be decomposed into elastic and (in
the plastic zone) plastic components:
.p~
e~~ ε+ε=ε (15)
Elastic strains are related to stresses by
]q)v21(vrvz[E1e
zε
]q)v21(zvrv[E1eε
]q)v21(zvvr[E1e
rε
−−θσ−σ−σ=
−−σ−σ−θσ=θ
−−σ−θσ−σ=
(16)
and at equilibrium
.ruθεand
drdu
rε == (17)
The radial displacement u(r) in the elastic zone is thus (since = 0) zε
( ) .2
rr)pq(rE
1)r(u −ν+
= (18)
To find the displacements in the plastic zone the flow rule (4) is needed. Since
1σ≡θσ and 3r σ≡σ , inserting (5) in (4) and eliminating d yields λ
(19) 0pzεand0p
θεprε
. ==+ &&l
and by summing the increments
(20) 0pzεand0
pθε
prε ==+ l
Combining (13), (15), (16), (17), (20) gives a differential equation for u : ( ) ⎥⎦
⎤⎢⎣⎡ +
−+=+ B1'kr
rA
Ev1
ru
drdu
l (21)
-8- Where
.)'pq()1()v21(B),'pp(]v)'k()v1()'k1[(A ++−−=++−−+= lll The solution, using the continuity of u at r = r from (18), is
( )⎥⎥⎦
⎤
⎢⎢⎣
⎡+
++
−⎟⎠⎞⎜
⎝⎛+
= 3k1
rr2k
1'kr
r2kr
Ev1)r(u
l (22)
where
B1
13k,A
'k1
1k+
=+
=ll
and .kkpqk 312 −−−= 5. Solution : third stage
The author (Reed 1986) has shown that the second stage will continue until
the tunnel support pressure p reaches the value P where
.'p)'pq(vv'k'k
v21p −+−−
−= (23)
At this point at the tunnel wall. If p drops further, an inner plastic
zone develops in which
zσ=θσ
.zr σ≤θσ<σ Let R denote the outer radius of this inner
plastic zone. To analyse this situation, we will consider the two cases (i) zσ=θσ
and (ii) in this zone separately, and show that (ii) is impossible. The
resultant situation is shown in fig. 3.
zσ<θσ
5.1 zr σ=θσ<σ in inner plastic zone.
In this case the stress solution for a and a. in the inner zone is still given by (13), since the relation c'r'k σ+σ=θσ still holds there. The interface
radius −r is also stil l given by (14), and zσ is given by (13) in the outer, and
in the inner zone. By equating θσ=σz zσ and θσ from (13), the boundary between
the inner and outer plastic zones is at
2'k1
'pp'pp
0rR −⎥⎦
⎤⎢⎣
⎡++
= (24)
-9-
Fig. 3
The analysis of the previous section for the radial displacement u(r) also
still holds in the outer plastic zone. The displacements in the inner plastic
zone will now be derived.
In the inner zone r0 < r < R the stress states lie on the intersection of
t h e t w o y i e l d s u r f a c e s 'cσrσk'θσ += a n d ,'cσrσk'zσ += t h a t i s o n o n e o f
the singularities of the yield surface generated by the Mohr-Coulomb condition in three-dimensional principal stress space. In these circumstances, Koiter (1953)
showed that the correct flow rule is obtained by summing the contributions from
the two plastic potentials
-10-
rz)~
(2Q
r)~
(1Q
σ−σ=σ
σ−θσ=σ
l
l (25)
to give
~
2Q2d
~
1Q1d~
pσ∂
∂λ+
σ∂∂
λ=ε& (26)
Eliminating and from the resulting three equations, gives 1dλ 2dλ
0.pzε
pθε
prε =++ &l&l& (27)
While the rock was in the outer plastic zone at earlier stages of the
deformation, the plastic strains satisfied (20), so that (27) may be integrated
to give
0.pzε
pθε
prε =++ l (28)
Using (13), (15), (16), (17) and with θσ=σz and ,0z =ε the differential
equation for the displacements in the inner plastic zone is
( )⎥⎥⎦
⎤
⎢⎢⎣
⎡+
−=+ D
1'kf
rcE1
ru
drdu
l (29)
where
.)'pq()v21()12(D
)'pp(]v)'k'k(2'k21[C+−+=
+++−+=l
lll
The solution for u(r) is
( ) ( ) ⎥⎦
⎤⎢⎣
⎡ ++
+−
= 3L1
rr2L
1'kr
r1LrE1)r(u
l (30)
where
l+= |1 k
1L C and 1
1L3 +=l
D. The coefficient L2 is found from the continuity
of u at r = R, using (22).
A more complicated, coupled analysis for stresses and displacements is
necessary with assumption (ii) . It will finally be shown, however, that the
resulting solution is inconsistent,
5.2 in inner plastic zone zr σ<θσ<σ
In th i s case , the s t r esses in the e las t i c zone rr > a re s t i l l g iven by (12) ;
in the outer plastic zone R rr << the equilibrium equation (6), yield surface (3)
and continuity of rσ give
-11-
q)v21()r(vz
'p1'k)rr()'pp(k
'p1'k)rr()'pp(r
−+θσ+σ=σ−−+=θσ
−−+=σ
(31)
although r is as yet undetermined. By equating zσ and at r = R, R is related to
θσr by
r1'k1
R −α= (32) where .
)'pp()'k'k()'pq()21(
+υ−υ−+υ−
=α The displacements in the outer plastic zone are
stil l given in terms of r by (22).
From (16), (31), (32), with = 0, the elastic strains at r = R can be deter-
mined, and it is found that = 0 on the outer-zone side of this boundary.
The plastic tangential strain is thus equal to the total tangential strain, which using (17) and (22) gives
exε
eθε
.3k1k1)(
α2kα1kE
1(R)θεpθ
~ε⎥⎥⎥
⎦
⎤
⎢⎢⎢
⎣
⎡
+−+
−+
υ+=≡
l
(33)
In the inner plastic zone, the failure surface |crkz σ+σ=σ (34)
gives rise to a flow rule which produces the relations
0p,0pz
pr =θε=ε+ε &&l& (35)
As in (33) is independent of the tunnel support pressure p and the boundary radius R , i t follows that this was the plastic tangential strain at
pθ~ε
each rock element when it passed into the inner plastic zone during the excavation process. By (20) the other plastic strains at this point are
0.p
z~εand
pθ
~ε
pr
~ε =−= l (3.6)
Summing the plastic strain increments once in the inner plastic zone, from (35),
.pθ
~εpθεand
pz
~εpθ
~εpz
~εpxε
prε ==+=+ l (37)
By (15) and the plane strain condition,
.pθ
~εeθεθεand
pθ
~εezε
erεrε +=−+= ll (38)
-12- Combining (6), (15), (16), (34), (38),
'c)v(dr
rdvr)1(r)]v2'k(v'kv1{[1drdu
σ−+σ
+−σ−+−−Ε
= lll
(39) ρθε−−+− ~}q)v21)(1( ll
and
.~r}q)v21('cvdr
rdrr)v'kv1{r1u Ρθε+−−σ−
σ+σ−−
Ε= (40)
Differentiating (40) and equating with (39) produces a second-order differential
equation in rσ , with general solution
Η++=σ 2n)R/r(G1n)R/r(Fr (41) where n1,n2 are the roots of
(42) 0)v2'k(n)vv'k2(2n =−−+−+ ll
and
H = .~1q)v21('cv2'k1
⎥⎦⎤
⎢⎣⎡ Ρ
θεΕ+
−−−σ−−
l
l (43)
F and G are determined from the boundary conditions at r = R, namely continuity
with the outer zone stresses (31):
]1n'p1n)'pp()1n1'k[(
2n1n1G
]2n'p2n)'pp~()2n1'k[(2n1n
1F
Η+++α−−−−
=
Η+++α−−−
= (44)
and R (and hence r by (32)) is expressed in terms of the tunnel support pressure
p by se t t ing .0rratpr ==σ F ina l ly , by subs t i tu t ing in to (40) the d i s -
placements u(r) are found. Note however that the nonlinear equation defining R
cannot be solved explicitly, and a numerical method such as Newton-Raphson must
be used.
When this analysis is applied to specific problems, and the resulting stresses
evaluated at points within the inner plastic zone (e.g. at the tunnel wall), it is
found that they violate the original assumption that θσ>σz . It will now be
shown that this is the case in general. This is done by proving that
dr
ddr
zd θσ>σ at r = R.
-13- Using (6), (34) and (41), at r = R
)G'k2nF'k1n(R1
drzd
+=σ
and .]G)2n1(2nF)1n1(1n[R1
drd
+++=θσ (45)
So using (44)
R .)H'p(2n1n)'pp()2n1'k)(1n1'k(dr
ddr
zd+−+α−−−−=⎟
⎠⎞
⎜⎝⎛ θσ−σ (46)
By (42), )v2'k(2n1nandv)'k(22n1n −−=−−=+ ll
so that by expanding (46) and using (32) and (43),
⎥⎦⎤
⎢⎣⎡
θεΕ++−−
+−++−−=θσ−
σ p~)1(vv'k'k
)'pq)(v21)(v1v'k2'k)(1'k(R1
drd
drzd
ll (47)
at r = R.
But the right-hand-side of (47) is the sum of two positive terms, if k' > 1,
l > 1 and 0 21v ≤≤ , so
.Rratdr
ddr
zd=θσ>
σ
Since θσ=σz at this point, and the derivatives are both positive at r = R since rσ is monotone increasing, it follows that there is a region on the inner-zone side of r = R in which on zσ>θσ .
The assumption zr σ<θσ<σ thus leads to a solution which is inconsistent, and the conclusion is zr σ=θσ<σ that in the inner plastic zone. 6. Problems with large drop in strength
From (14) and (24) it is seen that the ratio r/R is independent of the
tunnel support pressure p , so that once the inner zone is formed the inter-
zone boundar ies a t r and R wi l l move out toge ther . The outer p las t ic zone
wi l l only exis t i f r < R, and th is holds i f P < p ; subs t i tu t ing the def in i t ions
in (11) and (23) leads to
.p)'kk()pq(v1
1'cc −−−−
<σ−σ (48)
-14-
Thus, if the drop in strength upon yield is sufficiently large, this
condition may not be satisfied. In this case the whole plastic zone will have
; the other stresses are given by (13), the interface radius by (14 the displacements are given by (30) but with the coefficient L
θσ=σz ),
m 2 determined fro
the continuity of u at r using (10).
7. Numerical results
For problems involving only a small relative drop in strength upon yield, the influence of the out-of-plane stress upon the wall displacement will be minor.
For example, consider the data:
.3'kk,1.0;20'c,40c30, q ====υ=σ=σ= l
For this problem yield will first occur when p drops to p = 5. The inner
plastic zone will arise when p drops to P = 2.308, In Fig.4 a graph is plotted
of relative wall displacement against pressure difference q-p, as p drops 00 r/Eu
from 10 (when the rock is still elastic) to zero. The relative displacement ignoring
the effect of the out-of-plane stress (that is, using (22) throughout) is also
plotted in broken line, for comparison. When p = 0, the relative displacement is
70.269 using (30), compared with 69.300 using (22).
When the relative drop in strength is greater, the difference between the
true solution (30) and the two-dimensional solution (22) is more significant. For
the data:
5'kk,1.0,50'c,150c100,q ====υ=σ=σ= l the outer plastic zone starts when p = p - 8.333, and the inner plastic zone when
p = P = 7.955. The relative wall displacements at p = 0 are 264.78 using (30),
compared with 251.32 using (22). The corresponding graph is shown in Fig.5.
If the residual strength in the previous example is now reduced to 20,
then inequality (48) is no longer satisfied and the whole plastic zone has
. Now the relative wall displacements at p = 0 are 722.24 using (30), θσ=σz
and 618.32 using (22). The graph is given in Fig.6.
-15- 8. Conclusions
This paper has presented a complete analysis for the stresses and displace-
ments in the axisymmetric tunnel problem using a Mohr-Coulomb yield surface.
The deformation is shown to occur in three stages, in the last of which the out-
, the tunnel wall displacements can be significantly greater than those predicted of-plane stress influences the displacements in an inner plastic zone. For
materials with a large drop in strength at yield, or with a low Poisson's ratio
by an analysis which ignores this influence.
For more complex (and more realistic) situations involving material aniso-
tropy or non-circular tunnel profile, a numerical model is commonly produced by the finite element method. In this case the singularities of the yield surface, at which the flow vector would be indeterminate, are removed by 'rounding off the
corners'. Given the tendency of stress states in the plastic region to approach these corners, it is essential to evaluate the out-of-plane stress and plastic strain throughout the deformation when using the flow rule (4), if the numerical
solution is to converge to the correct displacement field.
9. Acknowledgements
The author is grateful to the Science and Engineering Research Council, and
British Coal for sponsoring a research project in which this work was performed.
10. References
FENNER, R. 1938 Untersuchungen zur Erkenntnis des Gebirgsdrucks. Diss. T. U. Breslau.
JAEGER, J.C. and COOK, N.G.W. 1979 Fundamentals of Rock Mechanics, 3rd ed.
London: Chapman & Hall. KOITER, W,T. 1953 Stress-strain relations, uniqueness and variational theorems
f o r e l a s t i c - p l a s t i c ma t e r i a l s w i t h s i n g u l a r y i e l d s u r f a c e . Qua r t . Appl. Math., 11, 350-354.
REED, M.B. 1986 Stresses and displacements around a cylindrical cavity in soft
rock. I.M.A. J. Appl. Math., 36, 223-245. TIMOSHENKO, S.P. and G00DIER, J.N. 1951 Theory of Elasticity New York: . McGraw-Hill
-16-
Fig:4
-17-
Fig 6
NOT TO BE REMOVED FROM THE LIBRARY